A distributed temperature profiling method for assessing spatial variability in ground temperatures in a discontinuous permafrost region of Alaska
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Published:2019-11-07
Issue:11
Volume:13
Page:2853-2867
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ISSN:1994-0424
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Container-title:The Cryosphere
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language:en
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Short-container-title:The Cryosphere
Author:
Léger EmmanuelORCID, Dafflon BaptisteORCID, Robert Yves, Ulrich Craig, Peterson John E., Biraud Sébastien C.ORCID, Romanovsky Vladimir E.ORCID, Hubbard Susan S.
Abstract
Abstract. Soil temperature has been recognized as a property that
strongly influences a myriad of hydro-biogeochemical processes and
reflects how various properties modulate the soil thermal flux. In spite
of its importance, our ability to acquire soil temperature data with high
spatial and temporal resolution and coverage is limited because of the high
cost of equipment, the difficulties of deployment, and the complexities of
data management. Here we propose a new strategy that we call distributed
temperature profiling (DTP) for improving the characterization and
monitoring near-surface thermal properties through the use of an
unprecedented number of laterally and vertically distributed temperature
measurements. We developed a prototype DTP system, which consists of
inexpensive, low-impact, low-power, and vertically resolved temperature probes
that independently and autonomously record soil temperature. The DTP system
concept was tested by moving sequentially the system across the landscape
to identify near-surface permafrost distribution in a discontinuous
permafrost environment near Nome, Alaska, during the summertime. Results
show that the DTP system enabled successful acquisition of vertically
resolved profiles of summer soil temperature over the top 0.8 m at numerous
locations. DTP also enabled high-resolution identification and lateral
delineation of near-surface permafrost locations from surrounding zones with
no permafrost or deep permafrost table locations overlain by a perennially
thawed layer. The DTP strategy overcomes some of the limitations associated
with – and complements the strengths of – borehole-based soil temperature
sensing as well as fiber-optic distributed temperature sensing (FO-DTS)
approaches. Combining DTP data with co-located topographic and vegetation
maps obtained using unmanned aerial vehicle (UAV) and electrical resistivity
tomography (ERT) data allowed us to identify correspondences between surface
and subsurface property distribution and in particular between topography,
vegetation, shallow soil properties, and near-surface permafrost. Finally,
the results highlight the considerable value of the newly developed DTP
strategy for investigating the significant variability in and complexity of
subsurface thermal and hydrological regimes in discontinuous permafrost
regions.
Publisher
Copernicus GmbH
Subject
Earth-Surface Processes,Water Science and Technology
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